Cycloalkanes are cyclic hydrocarbons, meaning that the carbons of the molecule are arranged in the form of a ring. Cycloalkanes are also saturated, meaning that all of the carbons atoms that make up the ring are single bonded to other atoms (no double or triple bonds). There are also polycyclic alkanes, which are molecules that contain two or more cycloalkanes that are joined, forming multiple rings.
Many organic compounds found in nature or created in a laboratory contain rings of carbon atoms with distinguishing chemical properties; these compounds are known as cycloalkanes. Cycloalkanes only contain carbon-hydrogen bonds and carbon-carbon single bonds, but in cycloalkanes, the carbon atoms are joined in a ring. The smallest cycloalkane is cyclopropane.
If you count the carbons and hydrogens, you will see that they no longer fit the general formula [latex] C_nH_ [/latex]. By joining the carbon atoms in a ring,two hydrogen atoms have been lost. The general formula for a cycloalkane is [latex] C_nH_ [/latex]. Cyclic compounds are not all flat molecules. All of the cycloalkanes, from cyclopentane upwards, exist as “puckered rings”. Cyclohexane, for example, has a ring structure that looks like this:
Figure 2: This is known as the “chair” form of cyclohexane from its shape, which vaguely resembles a chair. Note: The cyclohexane molecule is constantly changing, with the atom on the left, which is currently pointing down, flipping up, and the atom on the right flipping down. During this process, another (slightly less stable) form of cyclohexane is formed known as the “boat” form. In this arrangement, both of these atoms are either pointing up or down at the same time
In addition to being saturated cyclic hydrocarbons, cycloalkanes may have multiple substituents or functional groups that further determine their unique chemical properties. The most common and useful cycloalkanes in organic chemistry are cyclopentane and cyclohexane, although other cycloalkanes varying in the number of carbons can be synthesized. Understanding cycloalkanes and their properties are crucial in that many of the biological processes that occur in most living things have cycloalkane-like structures.
| Glucose (6 carbon sugar) | Ribose (5 carbon sugar) | Cholesterol (polycyclic) |
Although polycyclic compounds are important, they are highly complex and typically have common names accepted by IUPAC. However, the common names do not generally follow the basic IUPAC nomenclature rules. The general formula of the cycloalkanes is [latex] C_nH_ [/latex] where [latex] n [/latex] is the number of carbons. The naming of cycloalkanes follows a simple set of rules that are built upon the same basic steps in naming alkanes. Cyclic hydrocarbons have the prefix “cyclo-“.
For simplicity, cycloalkane molecules can be drawn in the form of skeletal structures in which each intersection between two lines is assumed to have a carbon atom with its corresponding number of hydrogens.
same as same as| Cycloalkane | Molecular Formula | Basic Structure |
| Cyclopropane | C3H6 | |
| Cyclobutane | C4H8 | |
| Cyclopentane | C5H10 | |
| Cyclohexane | C6H12 | |
| Cycloheptane | C7H14 | |
| Cyclooctane | C8H16 | |
| Cyclononane | C9H18 | |
| Cyclodecane | C10H20 |
The longest straight chain contains 10 carbons, compared with cyclopropane, which only contains 3 carbons. Because cyclopropane is a substituent, it would be named a cyclopropyl-substituted alkane.
| Cycloalkane | Cycloalkyl |
| cyclopropane | cyclopropyl |
| cyclobutane | cyclobutyl |
| cyclopentane | cyclopentyl |
| cyclohexane | cyclohexyl |
| cycloheptane | cycloheptyl |
| cyclooctane | cyclooctyl |
| cyclononane | cyclononanyl |
| cyclodecane | cyclodecanyl |
3) Determine any functional groups or other alkyl groups.
4) Number the carbons of the cycloalkane so that the carbons with functional groups or alkyl groups have the lowest possible number. A carbon with multiple substituents should have a lower number than a carbon with only one substituent or functional group. One way to make sure that the lowest number possible is assigned is to number the carbons so that when the numbers corresponding to the substituents are added, their sum is the lowest possible.
(1+3=4) NOT (1+5=6)
5) When naming the cycloalkane, the substituents and functional groups must be placed in alphabetical order.
6) Indicate the carbon number with the functional group with the highest priority according to alphabetical order. A dash”-” must be placed between the numbers and the name of the substituent. After the carbon number and the dash, the name of the substituent can follow. When there is only one substituent on the parent chain, indicating the number of the carbon atoms with the substituent is not necessary.
(ex: 1-chlorocyclohexane or cholorocyclohexane is acceptable)
7) If there is more than one of the same functional group on one carbon, write the number of the carbon two, three, or four times, depending on how many of the same functional group is present on that carbon. The numbers must be separated by commas, and the name of the functional group that follows must be separated by a dash. When there are two of the same functional group, the name must have the prefix “di”. When there are three of the same functional group, the name must have the prefix “tri”. When there are four of the same functional group, the name must have the prefix “tetra”. However, these prefixes cannot be used when determining the alphabetical priorities.
There must always be commas between the numbers and the dashes that are between the numbers and the names.
Notice that “f” of fluoro alphabetically precedes the “m” of methyl. Although “di” alphabetically precedes “f”, it is not used in determining the alphabetical order.
(2-fluoro-1,1,-dimethylcyclohexane NOT 1,1-dimethyl-2-fluorocyclohexane)
8) If the substituents of the cycloalkane are related by the cis or trans configuration, then indicate the configuration by placing “cis-” or “trans-” in front of the name of the structure.
Blue=Carbon Yellow=Hydrogen Green=Chlorine
Notice that chlorine and the methyl group are both pointed in the same direction on the axis of the molecule; therefore, they are cis.
9) After all the functional groups and substituents have been mentioned with their corresponding numbers, the name of the cycloalkane can follow.
Cycloalkanes are very similar to the alkanes in reactivity, except for the very small ones, especially cyclopropane. Cyclopropane is significantly more reactive than what is expected because of the bond angles in the ring. Normally, when carbon forms four single bonds, the bond angles are approximately 109.5°. In cyclopropane, the bond angles are 60°.
With the electron pairs this close together, there is a significant amount of repulsion between the bonding pairs joining the carbon atoms, making the bonds easier to break.
Alcohol (-OH) substituents take the highest priority for carbon atom numbering in IUPAC nomenclature. The carbon atom with the alcohol substituent must be labeled as 1. Molecules containing an alcohol group have an ending “-ol”, indicating the presence of an alcohol group. If there are two alcohol groups, the molecule will have a “di-” prefix before “-ol” (diol). If there are three alcohol groups, the molecule will have a “tri-” prefix before “-ol” (triol), etc.
The alcohol substituent is given the lowest number even though the two methyl groups are on the same carbon atom and labeling 1 on that carbon atom would give the lowest possible numbers. Numbering the location of the alcohol substituent is unnecessary because the ending “-ol” indicates the presence of one alcohol group on carbon atom number 1.
2,2-dimethylcyclohexanol NOT 1,1-dimethyl-cyclohexane-2-ol
3-bromo-2-methylcyclopentanol NOT 1-bromo-2-methyl-cyclopentane-2-ol
Blue=Carbon Yellow=Hydrogen Red=Oxygen
There are many other functional groups like alcohol, which are later covered in an organic chemistry course, and they determine the ending name of a molecule. The naming of these functional groups will be explained in depth later as their chemical properties are explained.
| Name | Name ending |
| alkene | -ene |
| alkyne | -yne |
| alcohol | -ol |
| ether | -ether |
| nitrile | -nitrile |
| amine | -amine |
| aldehyde | -al |
| ketone | -one |
| carboxylic acid | -oic acid |
| ester | -oate |
| amide | -amide |
Although alkynes determine the name ending of a molecule, alkyne as a substituent on a cycloalkane is not possible because alkynes are planar and would require that the carbon that is part of the ring form 5 bonds, giving the carbon atom a negative charge.
However, a cycloalkane with a triple bond-containing substituent is possible if the triple bond is not directly attached to the ring.
Name the following structures. (Note: The structures are complex for practice purposes and may not be found in nature.)
Draw the following structures.
Name the following structures.
Blue=Carbon Yellow=Hydrogen Red=Oxygen Green=Chlorine
2) chlorocyclopentane or 1-chlorocyclopentane
5) cyclopentylcyclodecane or 1-cyclopentylcyclodecane